KR20220061987A - Wireless power transaction system and method - Google Patents

Abstract

A power transaction system and method are provided. The system is a decentralized blockchain application that facilitates wireless power transactions between buyers and suppliers, wherein the blockchain application includes at least one blockchain ledger, wireless power two-part blockchain currency, the two-part blockchain currency comprises a first currency and a second currency; a trust server storing the two-part currency and fiat money; and a first server, the first server being on the at least one blockchain ledger. receiving fiat money from a purchaser transaction device in a recorded first transaction and exchanging the fiat money for two-part money from the trust server, wherein the first currency is provided to the purchaser transaction device and the second currency is maintained by the first server.

Description

Wireless power transaction system and method

Embodiments disclosed herein relate to power transaction, and specifically to a system, method, and apparatus for wireless power, data and/or information transaction using a block chain.

Space-based and high-zone solar power generation and transmission is a promising technology that can effectively meet the increasing energy demand and provides a safe, clean and non-depleting source of electrical energy. Solar power in space may offer advantages over solar power on the ground. These advantages include, for example, collecting sunlight directly from the sun without disturbances such as atmospheric loss or weather; collecting sunlight for a longer period of time than on the ground or collecting sunlight at all times depending on the location of the power generation satellite; always collecting sunlight from multiple orbits; and the ability to direct power to and between receiving stations; may be included.

As space-based solar power presents a potential global power solution, there is a need for systems and methods to facilitate global space-based solar transactions.

According to one embodiment, a wireless power transaction system is described herein. In another embodiment of the system, the system comprises a decentralized blockchain application that facilitates wireless power transactions between buyers and money changers, wherein the blockchain application facilitates recording and transmission of the wireless power transactions. and at least one blockchain ledger and one or more servers to arbitrate wireless power transactions through digital exchange of money based on the generation and use of power.

In another embodiment of the system, the system further comprises a wireless powered two-part blockchain currency, wherein the wireless powered two-part blockchain currency includes a first currency and a second currency.

In another embodiment of the system, the one or more servers include: a trusted server that stores the wireless powered two-part currency and fiat currency; and a first server, wherein the first server receives fiat money from a purchaser transaction device in a first transaction recorded on the at least one blockchain ledger and transfers the fiat money to the two-part from the trust server. In exchange for currency, the first currency is provided to a buyer transaction device and the second currency is held by the first server.

In another embodiment of the system, the system further comprises at least one wireless provider device for receiving and storing power, wherein the at least one wireless power purchaser device is configured to receive power from the at least one wireless provider device. can

In another embodiment of the system, the purchaser exchanges the first currency for power from the at least one wireless power provider in a second transaction recorded on the at least one blockchain ledger.

In another embodiment of the system, the at least one wireless power provider device and the first server provide to the trusted server in exchange for the fiat currency in a third transaction recorded on the at least one blockchain ledger. combining a first currency and a second currency, the fiat currency being provided to the wireless power supply device by the first server in a transaction recorded on the at least one blockchain ledger.

In another embodiment of the system, the system further comprises at least one wireless power transmitter for transmitting power.

In another embodiment of the system, the system further comprises a plurality of at least semi-autonomous aircraft, satellites, or ground-based devices configured as mobile transmitting and/or receiving power plants. A plurality of at least semi-autonomous aircraft, satellite or ground-based devices is configured as a mobile transmitting and/or receiving power plant, whereby the aircraft system navigates, maneuvers, beam rides and charges from one point to another. can do. The plurality of at least semi-autonomous aircraft, satellites, or land-based devices transmit power and data to and receive power and data from land-based and/or surface-based systems. to serve as power and data hubs connected to a plurality of tethers for further distributing power and/or data. the plurality of aircraft, satellite and ground-based devices consists of at least three, wherein the aircraft, satellite and ground-based devices are configured to transmit and receive quantum entanglement laser beams to exchange information; Aircraft, satellites, and ground-based devices are arranged in an equilateral or near equilateral triangle. Quantum entanglement may allow for secure and simultaneous communication between devices so constructed and deployed.

In another embodiment of the system, the at least one power transmitter comprises at least one solar satellite.

In another embodiment of the system, the system further comprises a plurality of reverse-directional antenna arrays for wireless transmission by base stations for receiving and transmitting power and/or data.

In another embodiment of the system, the at least one wireless power transmitter also transmits data.

In another embodiment of the system, the at least one blockchain ledger comprises at least one public blockchain and at least one private blockchain.

In another embodiment, a method of wireless power transaction is described herein. In another embodiment of the method, the method comprises: transmitting electromagnetic radiation from at least one solar satellite to at least one receiving station; and processing the purchase of power from the supplier transactional device by the purchaser transactional device.

In another embodiment of the method, a plurality of at least three aircraft, satellite or ground-based aircraft systems serve as receiving stations capable of navigating, maneuvering, beaming and charging from one point to another. There are devices. A plurality of at least semi-autonomous aircraft, satellites, or land-based devices transmit power and data to and receive power and data from land-based and/or surface-based systems to configured to serve as power and data hubs coupled to a plurality of tethers for further distributing power and/or data. wherein the plurality of at least semi-autonomous aircraft systems, satellite systems and ground-based devices consists of at least three, wherein the aircraft, satellite and ground-based devices are configured to transmit and receive a quantum entangled laser beam to exchange information. and the aircraft, satellites and ground-based devices are arranged in an equilateral or near equilateral triangle. Quantum entanglement may allow for secure and simultaneous communication between satellites so constructed and deployed.

In another embodiment of the method, the method further comprises processing the purchase by the purchaser transaction device of a first one of two-part money, the two-part currency being the first currency and a second currency. includes money.

In another embodiment of the method, the purchase includes: transferring fiat money to a first server by the purchaser transaction device; transferring the fiat currency by the first server to a trusted server; receiving, by a first entity, a two-part currency comprising a first currency and a second currency from the oracle server; and transferring the first currency to the purchaser transaction device by the first server; includes

In another embodiment of the method, the method further comprises recording a first transaction on a public blockchain, wherein the first transaction is a transfer of the fiat money to the first server by the purchaser transaction device. transfer and transfer of the first currency by the first server to the purchaser transaction device.

In another embodiment of the method, the purchasing comprises: transferring the first currency by the buyer transaction device to a supplier transaction device; and transmitting power from the at least one wireless power provider device to the at least one wireless power purchaser device; includes

In another embodiment of the method, purchasing comprises recording a second transaction on a public blockchain, wherein the second transaction comprises: a transfer of the first currency by the purchaser transaction device to the supplier transaction device; and transmission by the at least one wireless power provider device to the at least one wireless power purchaser.

In another embodiment of the method, the purchasing comprises: combining the first currency and the second currency into a two-part currency by the supplier transaction device and the first server; and transferring the two-part currency by the first server to the trust server; includes

In another embodiment of the method, the purchase records a third transaction on a public blockchain, wherein the third transaction comprises a transfer of the two-part money by the first server to the trusted server. -; transferring the fiat currency to the first server by the trusted server; and transferring the fiat currency to the provider device by the first server; includes

In another embodiment of the method, the purchasing comprises recording a fourth transaction on a private blockchain, wherein the fourth transaction comprises the transfer of the fiat currency by the first server to the supplier transaction device. do.

In another embodiment, a wireless energy transfer system is described herein. The system includes a decentralized blockchain application that facilitates wireless energy transfer between a receiver and a transmitter, the blockchain application comprising: at least one blockchain ledger; a first server, wherein the first server receives a request for wireless energy from the receiver, the request is recorded on the at least one blockchain ledger, and the first server is configured to send a request for wireless energy from the transmitter to the receiver. Facilitates wireless energy transfer.

In another embodiment of the system, the system further comprises at least one wireless power provider device for receiving and storing power, wherein the at least one wireless power purchaser device receives power from the at least one wireless power provider device. can receive

In another embodiment of the system, the transmitter exchanges the first currency for power from the at least one wireless power provider in a second transaction recorded on the at least one blockchain ledger.

In another embodiment of the system, the system further comprises a quantum secure blockchain network for wireless transmission by a plurality of nodes for receiving and transmitting power, data and/or information.

In another embodiment of the system, the system further comprises a plurality of at least semi-autonomous aircraft, satellite, or ground-based devices configured as mobile transmitting and/or receiving power plants, whereby the aircraft system is configured from one point to another. You can navigate, maneuver, beam piggyback and recharge. The plurality of at least semi-autonomous aircraft, satellites, or land-based devices transmit power and data to and receive power and data from land-based and/or surface-based systems. to serve as power and data hubs connected to a plurality of tethers for further distributing power and/or data. wherein the plurality of aircraft, satellite and ground-based devices comprises at least three, wherein the aircraft, satellite and ground-based devices are configured to transmit and receive quantum entanglement laser beams to exchange information; Ground-based devices are arranged in an equilateral or nearly equilateral triangle. Quantum entanglement may allow for secure and simultaneous communication between satellites so constructed and deployed.

In another embodiment, described herein is a wireless data transmission and communication system according to the quantum entanglement principle. In one embodiment, quantum entanglement is between a group of satellites. Such groups are arranged in a shape that resembles an equilateral triangle as closely as possible. A first satellite transmits a multi-bit entangled beam (eg, a laser beam) to a second satellite. Such a second satellite transmits the beam to a third satellite. Such third satellite again continues to transmit to the first satellite. More specifically, the first satellite polarizes the sequence to the satellite. The second satellite receives a sequence in which each bit is flipped. The second satellite repolarizes the sequence and transmits the sequence to the third satellite. The third satellite receives a signal in which each bit is flipped, and the third phase polarizes it and transmits it to the first satellite. Such systems advantageously allow real-time communication over virtually any distance using such triangular shapes and entangled beams.

Other embodiments and features will become apparent to those skilled in the art upon review of the following description of some representative embodiments.

The drawings included herein are intended to illustrate various examples of the articles, methods, and apparatus herein.

1 is a block diagram of a general computing device that may be used according to an embodiment.
2 is a schematic diagram of a network system including a blockchain for facilitating wireless power transactions, according to an embodiment.
3 is a block diagram of a solar-based space power generation and transmission system according to an embodiment.
4 is a block diagram of a wireless power transaction between a purchaser and a power provider, according to an embodiment.
5 is a block diagram of wireless power or data transmission between a receiver and a provider, according to an embodiment.
6 is a block diagram of a server of a computer system for wireless power transaction, according to an embodiment.
7 is a flowchart of a method for creating and approving a wireless power contract using a block chain, according to an embodiment.
8 is a block diagram of a business consortium for a wireless power transmission system, according to an embodiment.
9 is a flowchart of a method for requesting and receiving power/data from a transmitter by a receiver, according to an embodiment.
10A is a block diagram of a system for wireless data transmission and communication according to an embodiment.
FIG. 10B is a diagram illustrating a selection portion of the block diagram of FIG. 10A for a more detailed viewing of a quantum entanglement paradigm according to an embodiment.

Various devices or processes will be described below to provide representative examples of each claimed embodiment. The embodiments described below do not limit any claimed embodiment and any claimed embodiment may include other processes or apparatus than those described below. The claimed embodiments are not limited to an apparatus or process having all the features of any one apparatus or process described below, or features common to many or all of the apparatus described below.

One or more systems described herein may be implemented as a computer program running on programmable computers, each programmable computer including at least one processor, a data storage system (volatile and non-volatile memory and/or storage elements). ), including at least one input device and at least one output device. For example and without limitation, the programmable computers may include programmable logic units, mainframe computers, servers and personal computers, cloud-based programs or systems, laptops, personal data assistance, cell phones, smart phones. Or it may be a tablet device.

Each program is preferably implemented in a high-level procedural or object-oriented programming and/or scripting language for communicating with a computer system. However, if desired, the programs may be implemented in assembly or machine language. In any case, the language may be a compiled or interpreted language. Each such computer program is preferably a general purpose or special purpose programmable computer readable device or storage medium for configuring and operating a computer when read by the computer for performing the procedures described herein. stored on a device or storage medium readable by a programmable computer.

A description of an embodiment in which several components communicate with each other does not mean that all of these components are required. To the contrary, various optional elements are set forth to illustrate a wide variety of possible embodiments of the invention.

Also, although process steps, method steps, algorithms, etc. may be described in a sequential order (in this disclosure and/or claims), such process steps, method steps, and algorithms operate in an alternate order. can be configured. In other words, the order or sequence of steps that may be described does not necessarily represent a requirement that the steps be performed in that order or sequence of steps. The steps of the processes described herein may be performed in any order practicable. Also, some steps may be performed simultaneously.

Where a single device or article is described herein, it will be readily appreciated that two or more devices/articles (whether or not they cooperate) may be used in place of a single device/article. Likewise, when two or more devices or articles are described herein (whether or not they cooperate), it will be readily appreciated that a single device/article may be used in place of more than one device or article.

A system for establishing and maintaining a record of energy storage and use transactions for space-based energy is described below. Transaction records are maintained by the blockchain system. The system utilizes new monetary units created by energy production, power, data and/or information transfer, money transfer and/or energy, data and information storage.

The system can operate globally and on distributed networks, ie the system is not subject to or controlled by a single country or group of countries.

The system includes a “transaction contract” in which a transaction contract establishes ownership of the transferred energy. The transmitted energy may be used or stored by the recipient. The transaction contract may include payment to the energy transmitter in exchange for the received energy by the receiver.

The system is for energy that can be produced, used and stored on the ground and in space. The system may be arranged from a point on the ground to another point on the ground, from the ground to the ground, from the ground to the air, from the air to the ground, from the ground to the water, from the water to the ground, from the air to the air, from the air to the water, or from the water It can facilitate the transfer of energy and/or data under water. The system can be arranged from ground to space (spacecraft, satellite), space to ground, space to space, ground to space (spaceship, satellite), space to earth, space to space, earth to celestial body (e.g., to the moon, Mars, asteroids), from a celestial body to the ground, from space to a celestial body, or from a celestial body to space.

The amount of energy is a key component of the global rating system. Thus, a currency based on the production, use, and storage of available energy can have a stronger foundation for international transactions than existing systems. Advantageously, using the systems and methods of the present disclosure, as more energy is produced, including new green energy, more money can be in circulation. If money is removed from use, there may be a shortfall that can facilitate further production of energy.

The system may be used for transactions involving the transfer of energy in the form of wireless power, data or information. Advantageously, the system may transmit such power, data or information simultaneously or separately as needed.

Representative applications for the system include distributing power and/or data to mobile vehicles (eg, automobiles, boats, trains, airplanes, spacecraft, drones, satellites, etc.), powering Internet of things (IoT) devices, and the like. The above-mentioned embodiments of transactions for power generation and information distributed on the ground and in space, as well as delivering electricity and collecting data from sensors, and distributing power and/or data in a smart city will be included. can

1 is a simplified block diagram showing components of a device 1000 such as a mobile device or a portable electronic device. The device 1000 includes a number of components, such as a processor 1020 that controls operations of the device 1000 . Communication functions, including data communication, voice communication, or both, may be performed via communication subsystem 1040 . The data received by the device 1000 may be decompressed and decoded by the decoder 1060 . The communication subsystem 1040 may receive messages from the wireless network 1500 and may transmit messages to the wireless network 1500 .

The wireless network 1500 may be any type of wireless network including, but not limited to, a data-centric wireless network, a voice-centric wireless network, and a dual-mode network that supports both voice and data communications.

The device 1000 may be a battery powered device and includes a battery interface 1420 for receiving one or more rechargeable batteries 1440 as shown.

The processor 1020 may also include a random access memory (RAM) 1080 , a flash memory 1100 , and a touch-sensitive overlay 1140 (eg, together that together make up the touch-sensitive display 1180 ). display 1120 (connected to controller 1160), actuator assembly 1200, one or more optional force sensors 1220, auxiliary input/output (I/O) subsystem 1240, data port It interacts with additional subsystems such as 1260 , speaker 1280 , microphone 1300 , near field communication system 1320 , and other device subsystems 1340 .

In some embodiments, user interaction with the graphical user interface may be performed via touch-sensitive overlay 1140 . The processor 1020 may interact with the touch-sensitive overlay 1140 via the electronic controller 1160 . Information such as text, characters, symbols, images, icons, and other items that may be displayed or rendered on a portable electronic device generated by the processor 102 may be displayed on the touch-sensitive display 118 . In addition, user interactions may be performed in a mixed reality environment.

The processor 1020 may also interact with an accelerometer 1360 as shown in FIG. 1 . The accelerometer 1360 may be used to detect gravity or a direction of a repulsive force due to gravity.

In order to identify a subscriber for network access according to the present embodiment, the device 1000 includes a Subscriber Identity Module/Removable User Identity Module (SIM/RUIM) for communication with a network (such as the wireless network 1500 ). A SIM/RUIM card 1380 inserted into the interface 1400 may be used. Alternatively, the user identification information may be programmed into flash memory 1100 or performed using other techniques.

The device 1000 also includes an operating system 1460 and software components 1480 that may be executed by the processor 1020 and stored in a persistent data storage device, such as the flash memory 1100 . Additional applications may be directed to the device 1000 via a wireless network 1500 , an auxiliary I/O subsystem 1240 , a data port 1260 , a short-range communications subsystem 1320 , or any other suitable device subsystem 1340 . ) can be loaded onto

For example, in use, incoming signals such as text messages, e-mail messages, web page downloads, or other data may be processed by communication subsystem 1040 and input to processor 1020 . The processor 1020 then processes the received signal for output to a display 1120 or alternatively to an auxiliary I/O subsystem 1240 . Subscribers may also compose data items, such as e-mail messages, that may be transmitted over the wireless network 1500 via the communication subsystem 1040, for example.

In the case of voice communication, the overall operation of the portable electronic device 1000 may be similar. The speaker 1280 may output audible information converted from an electrical signal, and the microphone 1300 may convert the audible information into an electrical signal for processing.

Device 1000 may be used by a purchaser, supplier, receiver or transmitter in a wireless power transmission transaction or transfer.

2 is a block diagram illustrating a wireless power transaction system 200 according to an embodiment, wherein wireless power is energy transmitted wirelessly and used to run the device. The system 200 includes a server platform 202 that communicates via a network 210 with a plurality of buyer transaction devices 204 , a plurality of supplier transaction devices 206 , and a network of blockchain computers 208 . includes

Buyer transaction devices 204 and supplier transaction devices 206 may be desktop computers, notebook computers, tablets, personal digital assistants (PDAs), smartphones, or other computing devices (similar to device 1000 in FIG. 1 ). Devices 204 , 206 may include a connection to the server platform 202 , such as a wired or wireless connection to the Internet. In some cases, the server platform 202 may include multiple servers or other types of computer or communication networks.

Devices 204 , 206 may include one or more of memory, secondary storage, processors, input devices, display devices, and output devices. The memory may include random access memory (RAM) or a similar type of memory. The memory may also store one or more applications for execution by the processor. Applications may correspond to software modules comprising computer-executable instructions for performing processing for the functions described below. Secondary storage devices may include hard disk drives, floppy disk drives, CD drives, DVD drives, Blu-ray drives, or other types of non-volatile data storage. A processor may execute applications, computer readable instructions or programs.

The applications, computer readable instructions or programs may be stored in memory or secondary storage and may be received from the Internet or other server platform 202 . The input device may include any device for inputting information into devices 204 , 206 . For example, the input device may be a keyboard, keypad, cursor-control device, touch-screen, camera or microphone. The display device may include any type of device for presenting visual information. For example, the display device may be a computer monitor, flat-screen display, projector, or display panel. The output device may include any type of device for presenting hard copies of information, such as, for example, a printer. The output device may also include other types of output devices such as, for example, speakers. In some cases, devices 204 , 206 include any one or more of processors, applications, software modules, secondary storage devices, network connections, input devices, output devices, and display devices. can do.

Although devices 204 and 206 are described with various components, those skilled in the art will appreciate that devices 204 and 206 may include fewer, additional, or different components in some cases. Further, although embodiments of implementations of devices 204 and 206 may be described as being stored in memory, those of ordinary skill in the art will also recognize that such embodiments may also include secondary storage devices, including hard disks, floppy disks, CDs or DVDs; carrier waves from the Internet or other networks; or stored on or read from other types of computer program products or computer readable products, such as other types of RAM or ROM. The computer readable medium may include instructions for controlling the devices 204 , 206 and/or the processor to perform a particular method.

In the description below, buyer transaction devices 204 and supplier transaction devices 206 are described as performing specific actions. It will be appreciated that any one or more of these devices may perform an action, either automatically or in response to an interaction by a user of such device. In other words, a user of the device may operate one or more input devices (eg, a touchscreen, mouse, button, or gesture-based interaction) that cause the device to perform the described action. In many instances, such embodiments may not be described below, but will be understood.

As an example, it is described below that devices 204 , 206 may send information to server platform 202 . For example, a purchaser using the purchaser transaction device 204 may manipulate one or more input devices (eg, a mouse and keyboard) to interact with a user interface displayed on the display of the purchaser transaction device 204 . there is. Generally, the device may receive a user interface (eg, in the form of a webpage) from the server platform 202 . Alternatively, or in addition, the user interface may be stored locally on the device (eg, a cache of a mobile application or webpage).

Server platform 202 may be configured to receive a plurality of information from each of the plurality of purchaser transaction devices 204 and supplier transaction devices 206 . In general, the information may include at least an identifier identifying the purchaser or supplier. For example, the information may include one or more of a user name, e-mail address, password, or social media handle.

In response to receiving the information, the server platform 202 may store the information in a storage database. In general, the storage database may be any suitable storage device such as a hard disk drive, solid-state drive, memory card or disk (eg, CD, DVD or Blu-ray, etc.). Also, the storage database may be locally connected to the server platform 202 . In some cases, the storage database may be located remotely from the server platform 202 and may be accessible to the server platform 202 over a network, for example. In some cases, the storage database may include one or more storage devices located at a network cloud storage provider.

The buyer transaction device 204 may be associated with a buyer account. Likewise, the supplier transaction device 206 may be associated with a supplier account. Any suitable mechanism for associating a device with an account is explicitly contemplated. In some cases, a device may be associated with an account by sending credentials (eg, a cookie, login or password, etc.) to the server platform 202 . The server platform 202 may verify the credentials (eg, determine whether a received password matches a password associated with the account). Once a device is associated with an account, the server platform 202 may consider further actions by such a device associated with that account.

The server platform 202 is specially designed to manage wireless energy transactions or transfers, including the creation and recording of wireless energy transactions or transfers, and the creation and storage of data to facilitate the wireless energy transactions or transfers. It may be a manufactured machine.

The server 202 is connected to the blockchain network 208 via the network 210 .

The server 202 sends a transaction request to the blockchain network 208 . The transaction request includes various information and data regarding the proposed transaction between the buyer represented by the buyer transaction device 204 and the supplier represented by the supplier device 206 . A purchaser may be any individual or entity that consumes or stores wireless energy for future use.

The blockchain network 208 receives the transaction request from the server 202 and either approves or rejects the transaction request.

The blockchain network 208 includes at least one distributed ledger. The distributed ledger may be a blockchain. The blockchain network 208 may include one or more blockchain ledgers. For example, the blockchain ledger may be stored on a plurality of computers within the blockchain network 208 .

The blockchain ledger may be a private ledger or a public ledger. In one embodiment, the blockchain network 208 may store a plurality of blockchain ledgers. In this embodiment, the blockchain ledgers may include public ledgers and private ledgers.

In one embodiment, the blockchain network 208 comprises a decentralized and decentralized blockchain. Other blockchain architectures may be employed in other embodiments.

The interactions between the server 202 , the purchaser device 204 , and the supplier device 206 may be probed by the blockchain network 208 using blockchain ledger.

All interactions between devices 202 , 204 , 206 , whether successful or not, may be recorded on the blockchain ledger implemented by the blockchain network 208 .

As described above, the system 200 is configured to manage wireless energy transactions related to the transmission of power or data. A transaction managed by the system 200 may include the transfer of power from a power supplier to a power purchaser. Power is stored from a power source (the device or location from which power is generated) to a provider (any entity that supplies power or data to an end user) or a power storage device (not the power source and not directly supplying power to the end user). The transfer of power to any device that becomes

The blockchain network of system 200, and any other embodiments discussed herein, may be a quantum blockchain network, in which any or all transactions or interactions are quantum secured. These blockchains will use quantum key cryptography to maintain improved security compared to non-quantum blockchains that are vulnerable to hacking.

Referring now to FIG. 3 , a block diagram of a solar-based spatial power generation and power transmission system 300 according to an embodiment is illustrated in FIG. 3 . The solar-based spatial power generation and transmission system 300 converts solar energy into wireless power and then transmits the wireless power to the ground for storage and use. This wireless power is power that is bought and sold in the transactions shown in FIG. 3 .

The solar-based interphotovoltaic power generation and transmission system 300 includes a solar satellite 304 .

In the embodiment of Figure 3, there is a single solar satellite, but in other embodiments it may be in any type of orbit, may be at multiple orbital heights, and may be positioned at any location relative to each other and to the ground. It should be understood that there may be an array of satellites that may generate and transmit wireless power.

The solar satellite 304 receives solar energy from the sun 302 and receives information from a plurality of base stations 306 , 308 , 310 , 312 , 314 , 316 .

The plurality of base stations includes a mobile public base station 306 , base stations 308 , 310 , 312 , 314 , and a femto base station 316 . These base stations are devices capable of receiving wireless power from the solar satellite 304 and relaying that power to other devices and/or storing the wireless power. The base stations may receive the wireless power indirectly from the solar satellite 304 through a receiver (not shown) that directly receives the wireless power from the solar satellite 304 .

In the embodiment of FIG. 3 , transmission of wireless power is discussed but it should be understood that a solar satellite may transmit any electromagnetic energy and that energy may take the form of wireless power, data, or both.

Base stations 308 , 310 are located in first area 318 . The base stations 312 , 314 , 316 are located in the second area 320 .

The solar satellite 304 is powered by energy from the sun 302 . The solar satellite 304 converts energy from the sun 302 into microwave energy. The microwave energy may represent a form of wireless power. In other embodiments, solar satellites may convert solar energy into other forms of electromagnetic radiation.

Solar satellite 304 may transmit the converted solar energy (wireless power) to any one or more of mobile public base station 306 , base station 308 , base station 314 , and femto base station 316 . . The solar satellite 304 may transmit power wirelessly to base stations or other devices on the ground or on standby. Solar satellite 304 may transmit wireless power to devices in space, such as other satellites or spacecraft. The solar satellite 304 also transmits wireless power to any one or more of the mobile aerial base station 306 , the base station 308 , the base station 314 , and the femto base station 316 via a relay system. can

Solar satellite 304 is in an orbit that permits a constant or near constant supply of solar energy, such as a geostationary or solar synchronous orbit. In other words, the solar satellite 304 continuously or nearly continuously receives solar energy from the sun undisturbed. The ability of the solar satellite 304 to collect solar energy almost continuously provides a significant advantage over terrestrial solar energy technologies. The solar satellite 304 may occupy multiple orbits to transmit wireless power to a plurality of mobile aerial base stations 306 , base stations 308 , base stations 314 , and femto base stations 316 .

Solar satellite 304 is shown transmitting power to first and second regions 318 , 320 . The solar satellite 304 may transmit wireless power to the two regions 318 , 320 simultaneously or at separate times. Areas 318 and 320 are separated by a distance that does not allow simultaneous transmission of wireless power. The solar satellite 304 may change its position in space relative to its terrestrial position. This position change may require the satellite 304 to change its orbit position (if the orbit is stationary) or may simply require the passage of time (if the orbit is non-stationary).

The ability to transmit to multiple base stations in different locations or in different areas, such as land and air, land and space, space and air, may depend on the number of transmission outputs the solar satellite 304 has; Here, the transmit output(s) is the output(s) of the satellite 304 that transmits or beams power to a destination. In other words, the solar satellite 304 may have multiple outputs capable of transmitting power such that the solar satellite 304 can transmit multiple power beams simultaneously. The solar satellite 304 may have the ability to change the entire satellite 304 with reference to a target base station using active and passive station maintenance techniques, or where a digital beam forms the location of transmission outputs. In other words, the transmission outputs may be adjusted relative to the body of the satellite 304 while the satellite 304 may travel to another predefined input or reference point relative to the ground, thereby changing the transmission path of power from the transmission output. Alternatively, the transmission outputs may be associated and travel with respect to the body of the satellite 304 such that the transmission path of power from the transmission output travels with respect to both the satellite 304 and the ground.

The ability of a satellite 304 to transmit to more than one base station at a time may be limited by the range of the satellite. For example, the satellite may transmit only to several base stations located in areas that are within a certain distance from each other.

The ability of the solar satellite 304 to not transmit energy to different regions simultaneously may depend on the particular locations of the regions with respect to the location of the solar satellite 304 and its orbit.

Solar satellite 304 may also transmit data to base stations 306 , 308 , 310 , 312 , 314 , 316 . The transmitted data may be transmitted with energy to be used as wireless power. The transmitted data may be transmitted as microwave energy.

Base stations 306 , 308 , 310 , 312 , 314 , 316 may transmit the received data to one or more recipient devices. The receiver device may be a server, computer, phone, car, airplane, drone, train, or the like. The data may be transmitted from the base station 306, 308, 310, 312, 314, or 316 to the receiving device in any suitable form.

The transmitted data may be integrated or combined with microwave energy transmitted by the satellite 304 as wireless power.

The transmitted data may be filtered from the same beam as the wireless power. The transmitted data may be within a pilot beam or may include entirely pilot beams, where a pilot beam is a beam transmitted from a transmitter to a receiver to establish and maintain a connection.

The satellite 304 may be configured to use certain frequencies of microwave energy to represent other frequencies and data for wireless power energy. In some cases, the satellite may transmit data using frequency fluctuations.

Currently, a typical technology for receiving both power and data is a chip on a contactless card. The chip receives both data and power via a radio frequency magnetic field.

Transmitting data as microwave energy from the solar satellite 304 may allow for the transmission of larger data files. For example, instead of streaming information or sending information in small packets, a large file can be sent all at once. The data may be encrypted more securely when transmitted in this way, for example via quantum encryption.

The transmitted data may be transmitted alone or with wireless power. The transmitted data can have multiple uses. For example, the transmitted data can be used to recalibrate sensors on the ground and/or sensors on a satellite array, where the solar satellite 304 can be referenced to ensure that all sensors in the array are as accurate as possible. is the point where

The wireless power generated by system 300 may be used immediately or stored in any device capable of storing energy, such as a battery (eg, car battery, household battery, phone battery, etc.).

In other embodiments, the solar space power generation and transmission system 300 may include a satellite array. The satellites in the satellite array may be in different orbital positions (eg, geostationary orbit (GEO), medium Earth orbit (MEO), or low Earth orbit (LEO)). MEO and LEO are less restrictive than GEO in terms of space and orbit restrictions in which satellites are provided, thus providing more opportunities to create arrays of satellites.

Each satellite in the satellite array may be configured to generate and store energy, only produce energy, or only store energy received from other satellites. In-space energy storage has the added benefit of ameliorating the loss of stored power that occurs when energy is stored on the ground. Energy can be stored indefinitely in space without significant loss or by making up for the loss by use of other power generated.

Each satellite in the satellite array may be configured to transmit energy and data and receive data.

Referring now to FIG. 4 , there is shown a block diagram of a wireless power transaction 400 according to an embodiment. The transaction 400 may be implemented using the system 200 of FIG. 2 .

The transaction 400 uses a two-part blockchain currency that is created and stored by the system 100 . The two-part blockchain currency includes a first currency and a second currency.

This two-part currency is referred to herein as "voltierra". The first currency is referred to herein as a “volt” and the second currency is referred to herein as a “tier”. However, these names are examples only and other names may be used for the two-part money, the first currency or the second currency.

In FIG. 4 , a volt is represented by a lightning bolt, a tiera is represented by an ellipse, and the combined Volterra currency is represented by a lightning bolt on the ellipse. Fiat money is denominated with the dollar symbol.

Transaction 400 includes a purchaser 402 , a first server 404 , a trusted server 406 and a power provider 408 . Buyer 402 may use a purchaser device similar to purchaser device 202 of FIG. 2 . The power provider 408 may use a provider device similar to the provider device 206 of FIG. 2 . The first server 404 or trusted server 406 may be similar to the server 202 of FIG. 2 . Generally, in transaction 400 , purchaser 402 wants to purchase wireless power from power provider 408 and binds with first server 404 and indirectly binds with trusted server 406 to provide power provider ( 408) to facilitate wireless power transactions. All embodiments of the transaction are recorded on the blockchain.

The transaction 400 includes a plurality of currency exchanges between a purchaser 402 , a first server 404 , a trusted server 406 , and a power provider 408 . Currency exchanges are indicated by arrows. The striped arrows represent exchanges recorded on the public blockchain ledger. The dotted arrows represent exchanges recorded on the private blockchain ledger. Solid black arrows indicate exchanges that do not include a blockchain. The wireless power 410 is indicated by a power symbol. The transaction 400 is performed as follows.

The purchaser 402 purchases the bolt through the first server 404 from the trusted server 406 through the following steps.

The first server 404 receives fiat money from the purchaser 402 .

The first server 404 exchanges fiat money from the trust server 406 for an equivalent amount of voltieras (volts + tieras).

The first server 404 provides the bolts to the purchaser 402 while holding the Tierra.

Next, the purchaser 402 purchases power from the power provider 408 using volts through the following steps.

The purchaser 402 provides the volts to the power supplier 408 .

The power provider 408 combines the volts with the tier from the first server 404 (ie, the tier previously held by the server 404 ) and the resulting voltiera is provided to the trusted server 406 .

The trust server 406 sends fiat money to the first server 404 . The amount of fiat money is determined from the received Baltiera. The first server 404 provides fiat money to the power provider 408 .

After receiving the fiat currency, the power provider 408 provides wireless power 410 to the purchaser 402 .

Examples of such transactions could include a buyer and a supplier using a smartphone to initiate a transaction via a QR code. The supplier may have the QR code scanned by the buyer's smartphone on his smartphone. During scanning, funds can be transferred from the buyer to the supplier, and as above, wireless power can be transmitted from the supplier's storage location to the buyer's desired device. Transactions are instantaneous and secure.

In the embodiment of Figure 4, a proprietary two-part currency is used. In other embodiments, conventional cryptocurrency or fiat currency may be used.

Referring now to FIG. 5 , a block diagram of a wireless energy transfer 500 according to an embodiment is shown. The wireless energy transfer 500 may be implemented using the system 200 of FIG. 2 . Transfer 500 is similar to transaction 400 but does not include two-part money. Transfer 500 may also include transmission of wireless power, data and/or information, or any other type of wireless energy. Transfer 500 includes customer 502 , first server 504 , trust server 506 , and provider 508 . Data passed between the customer 502 , the first server 504 , the trusted server 506 and the provider 508 is indicated by black arrows. Such data may be requests, approvals, proofs of approval, and the like. The transfer of wireless energy in the form of power, data and/or information from the supplier 508 to the customer 502 is indicated by striped arrows.

Customer 502 is similar to purchaser 402 of FIG. 4 . The customer 502 may obtain wireless energy from the provider 508 in exchange for something other than fiat currency, such as cryptocurrencies, other data, and the like.

The customer 502 sends an authorization request to the first server 504 . The permission request requests permission for acquisition of wireless energy. Such permission requests may contain non-fiat currency or data of any kind.

The first server 504 interacts with the trust server 506 to evaluate the authorization request. Evaluating the authorization request includes determining the eligibility of the customer 502 to receive power/data/information based on the authorization request.

The interactions in the transfer 500 between the customer 502 , the first server 504 and the trust server 506 are indicated by solid arrows. These interactions can be recorded and performed and permission can be granted on at least one blockchain.

The customer 502 sends a transfer request to the supplier 508 . The transfer request requests wireless energy transfer with the provider 508 .

The provider 508 sends the transfer request to the trust server 506 . The first server 504 sends an authorization certificate to the trusted server 506 . The request and the grant may be sent together or separately to the trust server 506 . When the request and the grant are sent together, the request may be received by the first server 504 and sent along with the permission to the trusted server 506 .

Interactions including the transfer of the transfer request and the permission are recorded on one or more blockchains.

The trust server 508 checks all relevant data (the identity of the buyer, the identity of the supplier, the nature of the request, etc.) and either accepts or rejects the requested transfer. The trust server 508 provides a notification of acceptance or rejection of the requested transfer to the first server 504 . Such acceptance or rejection is recorded on at least one blockchain.

The first server 504 sends an accept or reject to the provider 508 . If the transfer is accepted, the supplier 508 transfers the wireless power to the customer 502 .

By implementing transfer 500 including an authorization mechanism, the system pre-authorizes a wireless energy receiver (eg, customer 502 ), thereby allowing only pre-approved receivers to make requests from suppliers.

In some cases, the customer 502 may only receive wireless power from the provider 508 . In some cases, the customer 502 may only receive data or information from the supplier 508 . In some cases, the customer 502 may receive both wireless power and data from the provider 508 .

6 is a block diagram of a server 600 of a computer system for wireless power transactions, according to one embodiment. Server 600 may be similar to server 202 of FIG. 2 , server 404 of FIG. 4 , and server 504 of FIG. 5 .

The server 600 includes a memory 610 and a processor 620 . Memory 610 may store instructions that, when executed, cause server 600 to perform functions or other actions of the methods discussed herein.

Memory 610 includes buyer ID data 611 , buyer request data 612 , approval data 613 , trust server data 614 , supplier data 615 , transaction data 616 , blockchain data 617 . , and monetary data 618 are stored.

The processor 620 includes a buyer approval module 621 , a trust server approval module 622 , a blockchain module 623 , an identity module 624 , a buyer transaction module 625 , a trust server transaction module 626 , and a supplier transaction module 627 .

Although the term “buyer” is used in connection with FIG. 6 (eg, buyer approval module 621 ), the term is not limited to people or entities that receive power or data in exchange for money. The purchaser may also include any individual or entity that receives power or data in exchange for something other than monetary, such as data.

The computer system in which the server 600 functions may be similar to the computer system of FIGS. 2 , 4 and 5 .

The server 600 is configured to perform various functions related to a wireless power transaction in which a purchaser requests wireless power from a provider (eg, transaction 400 of FIG. 4 , transaction 600 of FIG. 6 ).

Server 600 receives buyer ID data 611 and buyer approval data 612 from a buyer, for example, via buyer transaction device 104 of FIG. 2 . The server 600 stores the purchaser ID data 611 and the purchaser approval data 612 in the memory 610 .

The purchaser ID data 611 may be any data that identifies the purchaser. For example, purchaser ID data 611 may include personally identifiable information, financial information (eg, bank account information, credit card information, etc.) or the like.

Buyer approval data 612 may be any data that may be used to approve a purchaser as entitled to receive power/data. Buyer authorization data 612 may include, for example, currency, evidence that the buyer has the funds or data needed to transfer, evidence of location, evidence of past successful transactions, or the like.

Data transmitted by Buyer may be transmitted from a computer, telephone, or other Buyer device capable of transmitting such data.

Buyer approval module 621 sends buyer ID data 611 and buyer approval data 612 to a trust server (eg, trust server 406 of FIG. 4 or trust server 506 of FIG. 5 ).

The trust server generates trust server data 613 (using buyer ID data 611 and buyer approval data 612 ). The trusted server returns the trusted server data 613 to the server 600 . Trust server data 613 is provided as input to trust server authorization module 622 . Trust server data 613 includes information that either approves the buyer as a prospect for over-the-air transactions or rejects (ie, does not approve) the buyer as a prospect.

This interaction between the server 600 and the trust server and the subsequent approval or rejection of the purchaser may be made or recorded on at least one blockchain. The blockchain module 623 transmits, receives, or transmits and receives data to and/or from at least one blockchain in connection with the purchaser's approval. Blockchain data 616 relating to and/or received from the at least one blockchain is stored in the memory 610 .

In an embodiment where two-part money is used for a wireless power transaction, such as in transaction 400 of FIG. 4 , the buyer's approval is that the buyer receives a first fraction of the two-part money in exchange for fiat money. It can be a transaction. Buyer approval data 612 may be fiat currency in electronic form. In such embodiments, the trust server stores the two-part money and provides the two-part money to the server 600 in exchange for fiat money from the purchaser (buyer approval data 612 ). The server 600 provides the first portion of the two-piece currency to the purchaser while holding the second portion of the two-piece currency. In this embodiment, trust server data 613 represents a two-part currency.

In one embodiment, purchaser approval may require confirmation that the purchaser's known identity is genuine and/or that the purchaser has the data or funds necessary for the wireless power transaction.

Once the purchaser has been approved and/or has received the first portion of the two-part money, the purchaser sends a request to receive wireless power (or data) to the supplier. The request is indicated as transaction data 615 . Provider data 614 is stored in memory 610 of server 600 . The supplier data may be any identifying data about the supplier or data related to the power/data currently available to the supplier. The provider sends the transaction data 615 to the server 600 . The transaction data 615 is stored in the memory 610 of the server 600 .

The supplier transaction module 625 receives the transaction data 615 from the supplier and examines the transaction details against the supplier data 614 and the buyer ID data 611 to verify the IDs of the parties.

The trust server transaction module 626 sends the buyer ID data 611 , the trust server data 613 , the supplier data 614 , and the transaction data 614 to the trust server. The trust server checks all data against buyers, suppliers, and its own data about possible transactions between buyers and suppliers. The eligibility determination is returned to server 600 as more trusted server data 613 stored in memory 610 .

The blockchain module 623 publishes the presented transaction on the blockchain using the buyer ID data 611 , trust server data 613 , supplier data 614 , and blockchain data 616 . Nodes in the blockchain network approve or reject transactions until a consensus is reached on the transaction. The consensus decision is returned to the server 600 as additional blockchain data 616 .

When the transaction is approved by the blockchain network, the purchaser transaction module 627 sends an authorization to the buyer and supplier and the transaction proceeds.

If the transaction is rejected by the blockchain network, the buyer transaction module 627 sends a rejection to the buyer and supplier and the transaction is not made.

Server 600 may facilitate transfer of power or data from a supplier to a buyer/receiver. Server 600 may facilitate transfer of power from a power source to a provider (ie, a power provider) for storage.

In the embodiment of FIG. 6 , server 600 facilitates wireless power transactions as in FIG. 4 , but in other embodiments a server similar to server 600 may contain power, data, or other information between the parties. It may facilitate the transfer of any form or wireless energy.

Referring now to FIG. 7 , a flowchart of a method 700 for creating and authorizing a wireless power contract using a blockchain is shown in FIG. 7 . The method 700 may be performed by a wireless power transaction system, such as system 100 of FIG. 2 .

At 702, the purchaser creates a wireless power contract. The wireless power contract includes data about the requested wireless power transaction. The data includes the purchaser ID, how the purchaser intends to purchase wireless power (ie, the type of currency or data to provide in exchange for wireless power), the exact amount of wireless power requested, the date and time of transmission of the requested wireless power; It may include a specific provider, the type of device receiving the power, and other pertinent information.

At 704, the contract is posted on the blockchain. The blockchain may be a decentralized and decentralized blockchain.

At 706 , a contract modeler downloads the contract data and trains the model. The model is limited to contract data provided by the purchaser.

The contract modeler may be a person skilled in the task of training a model, such as a machine learning engineer, a software engineer and/or subject matter expert. The contract modeler may be software (eg, a neural network). The software may have been trained by a person skilled in the task, for example a machine learning engineer.

At 708, the model is proposed for the blockchain. The model can be proposed for the blockchain by the contract modeler.

At 710, the model is run on the blockchain. Execution of the model may include nodes on the blockchain network examining the model and accepting or rejecting the model. Inspection of the model may include generating a majority decision. The majority vote may represent decisions from all nodes on the blockchain network. The majority vote may determine whether the model is approved or rejected.

At 712 , if all conditions of the contract are met, the model is sent to the buyer. The payment is sent to the contract modeler.

At 714 , the contract is fulfilled. The purchaser receives wireless power from the supplier. In one embodiment, the purchaser may receive wireless data from the provider instead of wireless power and the purchaser may receive both data and power from the provider.

8 is a block diagram of an exemplary business consortium 800 for a wireless power transmission system, according to an embodiment.

The consortium 800 represents an embodiment of a business model for a wireless power transmission system. Consortium 800 includes a governance board 802 , founding members 804 , consortium promoters 806 , participating members 808 , consortium decisions 810 , operating rules 812 , consortium agreements 814 , Consortium Manager 816, Shared Ledger Platform 818, Decision on Implementation of Ledger 820, Smart Contract System 822, Rules Engine 824, Technology Provider 826, Non-Participating Member 828, and participant agreement 830 . The consortium 800 functions as follows.

The governance board 802 includes a plurality of members who make decisions regarding how the consortium 800 operates, namely, a founding member 804 , a consortium promoter 806 , and a participating member 808 . The governance board 802 may also include members other than one of the three groups 804 , 806 , 808 .

Founding member 804 is a member of a consortium that has been part of the business model since its inception. The consortium promoter 806 is not directly involved in the founding of the consortium 800 and cannot directly participate in the business model, but is an investor or a member of the consortium 800 promoter. The participating member 808 is a member that participates in the consortium but is not yet a member at the time of establishment of the business model. Participating members 808 may have fewer rights within consortium 800 than founding members 804 .

The governance board 802 is responsible for the consortium decision 810 . This decision 810 may be any decision that affects the business model and the way the consortium 800 operates. The consortium decision 810 may affect the operating rules 812 of the consortium 800 . The operating rules 812 are included in the consortium agreement 814 . All members of consortium 800 (eg, founding member 804 , consortium promoter 806 , and participating member 808 ) agree to consortium agreement 814 and consequently comply with operating rules 812 . agree to The technology provider 826 must also follow the operating rules 812 .

The consortium 800 implements wireless power transactions using blockchain technology and systems.

The consortium manager 816 manages the operation of the consortium 800 at the level of the shared ledger platform 818 and does so in direct response to decisions and information from the governance board 802 . The consortium manager 816 may be at least one person implementing the decision and the consortium manager 816 may be a computer program designed to implement the decision.

The shared ledger platform 818 includes at least one blockchain ledger for recording and storing transactions. Blockchain ledgers can be public decentralized ledgers or private decentralized ledgers. A blockchain system may include multiple ledgers. In embodiments using multiple ledgers, the ledgers may be public ledgers, private ledgers, or both.

The governance board 802 also makes decisions about the implementation of the ledger 820 . Decisions about the implementation of the ledger 820 are implemented in the blockchain's smart contract system 822 as well as the blockchain's rules engine 824.

Smart contract system 822 and rules engine 824 are computer components of a blockchain system and may include artificial intelligence or machine learning components, as well as servers, computers, and other types of communication devices.

Shared ledger platform 818, smart contract system 822, and rules engine 824 together determine which transactions can be completed. The technology provider 826, which may include a wireless power provider to a consortium customer, is notified of a decision to allow the transaction to take place once the transaction is approved by the blockchain.

In addition to the members discussed above, non-participating members may join a consortium by signing a participant agreement 830 to become a participating member 808 .

The consortium 800 may be distributed worldwide. Nodes within founding member 804 , consortium promoter 806 , participating member 808 , non-participating member 828 , technology provider 826 , and shared ledger platform 818 may be located anywhere. The absence of local control of the consortium 800 may advantageously facilitate a global system for green energy consumption where the cost of wireless power is not determined by a monopoly.

Referring now to FIG. 9 , shown is a flow diagram of a method 900 of requesting and receiving power/data from a transmitter by a receiver. The method 900 includes a purchaser or receiver of wireless power, such as purchaser 402 of FIG. 4 or customer 502 of FIG. 5 , a supplier or transmitter such as power provider 408 of FIG. 4 or supplier 508 of FIG. 5 . Describes the steps required to receive power/data from

At 902, a pilot signal is transmitted by the receiver. The pilot signal requests a connection with the transmitter. The transmitter is configured to transmit power, data or power and data. The pilot signal may include identification information for the receiver.

At 904 , a bidirectional communication link is established between the receiver and the transmitter.

A bidirectional communication link can be established when the transmitter recognizes and acknowledges the receiver based on any identifying information or specific request information sent to the transmitter.

At 906 , power and/or data requested by the receiver is transmitted from the transmitter to the receiver. The pilot signal is used as a location beacon. Power and/or data may be transmitted from the transmitter to the receiver via the reverse path of the pilot signal, thereby ensuring that power and/or data are received by the receiver. The connection between the receiver and the transmitter may be maintained for at least as long as required for the requested power and/or data to be transmitted from the transmitter to the receiver.

At 908 a "payment" is processed. Payment is processed from the receiver to the transmitter once the requested power and/or data is delivered to the receiver. Payments may be made in the form of fiat currency, two-part money (eg, the two-part currency “Voltierra” in FIG. 4 ), or other forms of cryptocurrency (eg, established cryptocurrencies such as Bitcoin). Payment may be made with some other form of data transmitted from the receiver to the transmitter in return for received power and/or data. For example, a transfer of power and/or data may be made from a power source to a storage point and consequently no currency exchange may occur as no power/data is transmitted to the customer.

At 910, a transaction between the receiver and the transmitter is recorded on at least one blockchain ledger.

The blockchain ledger may be a public ledger or a private ledger. Users of Blockchain Ledger (as in Figure 8), power and/or data providers, and regulators of blockchain or wireless power/data consortia review and validate transactions to ensure that the transmission of power and/or data was as expected. can be verified. Even if the transaction being made does not involve a customer and simply involves, for example, the movement of power from a power source to a storage point or from a storage point to another storage point, the transfer of power/data is at least one blockchain ledger. recorded on the

At 912 , the connection between the receiver and the transmitter is terminated once the correct transfer of power and/or data is confirmed.

Referring now to FIG. 10A , a block diagram of a wireless data transmission and communication system 1000 according to an exemplary embodiment is illustrated in FIG. 10A . Also, referring to FIG. 10B , a selection portion 1020 of the block diagram of FIG. 10A is illustrated in FIG. 10B . Selection 1020 of FIG. 10B is at a scale that allows identification of each of the entangled beams 1014c, 1014d, 1014e, etc. transmitted between the three satellites 1004, 1006, 1008, and the three satellites 1004, 1006, 1008. ) shows the desired triangle arrangement.

System 1000 is built according to the principle of quantum entanglement between several satellites 1018a, 1018b, etc. Each group of satellites 1018a, 1018b, etc. is arranged in a shape that approximates an equilateral triangle as much as possible.

The system 1000 further includes a plurality of at least semi-autonomous aircraft, satellite, or ground-based devices 1018a, 1018b, etc. configured as mobile transmitting and/or receiving power plants. A plurality of at least semi-autonomous aircraft, satellite or ground-based devices is configured as a mobile transmitting and/or receiving power plant, through which the aircraft system can navigate, maneuver, beamboard and charge from one point to another. . The plurality of at least semi-autonomous aircraft, satellites, or ground-based devices 1018a, 1018b, etc. transmit power and/or data to a land-based and/or water-based system such as a 1018k or 1018i and transmit power and/or data to a 1018k or The role of power and data hubs connected to a plurality of tethers, such as 1014a, 1014b, etc., to receive power and/or data from a land-based and/or water-based system such as 1018i to further distribute power and/or data is configured to do The plurality of aircraft, satellites, and ground-based devices (1018a, 1018b, etc.) consists of at least three, and the aircraft, satellites, and ground-based devices (1018a, 1018b, etc.) emit quantum entanglement laser beams (1014a, 1014b, etc.). and transmit and receive to exchange information, wherein the aircraft, satellites, and ground-based devices 1018a, 1018b, etc. are arranged in an equilateral or near equilateral triangle as in group 1012 . Quantum entanglement may allow for secure and simultaneous communication between devices so constructed and deployed.

Within selection portion 1020 , satellites 1004 , 1006 , 1008 make up group 1012 of satellites. The group 1012 is arranged in a shape that is as close to an equilateral triangle as possible. Group 1012 is near planet earth 1002 . Group 1012 consists of satellites 1004 in the air, satellites 1006 in outer space, and satellites 1008 in the ground. These satellites are arranged in an equilateral triangle shape. The shape of an equilateral triangle is almost entirely through its ability to switch between nodes, regardless of whether a continuous array of satellites, aircraft, and ground-based devices are positioned as shown, in further outer space, or on planets or celestial bodies. Enables simultaneous communication. When using quantum entanglement, this communication paradigm is secure and simultaneous with inter-satellite transmission of entanglement beams 1014c, 1014d, 1014e, etc.

Satellite 1006 receives an entangled beam 1014c from satellite 1004 . Beam 1014c includes a sequence, for example 100011 . The satellite 1006 then polarizes the sequence 100011 and transmits it as information 011100. The satellite 1006 polarizes the sequence 100011 by changing the polarization. Satellite 1006 continues to change polarization until a connection is determined. The step of changing the polarization until a junction is determined is performed at all six junction points as shown by the three beam pairs 1014c, 1014d; 1014e, 1014f; and 1014g, 1014h. Satellite 1008 immediately receives signal 1014e, eg, 011100, from satellite 1006 as a depolarized beam. Satellite 1008 polarizes a signal, for example 100011 , which it receives from satellite 1004 via beam 1014g. Satellite 1006 receives beam 1014f polarized in an inverse manner, for example 011100. Through operation of the satellites forming an equilateral triangle in group 1012, all three satellites 1004, 1006, 1008 may have the same information. Satellites 1004 , 1006 , 1008 obtain the same information by determining the source of beam 1014 and inverting that beam as necessary. Receiving satellite 1004, 1006 or 1008 may also respond in reverse order. All of these tasks can be performed regardless of the actual distance between the satellites.

In another embodiment, described herein is a set of nodes, such as autonomous or semi-autonomous satellites, that can be deployed in the field and can communicate with each other using the system to communicate with each other. When using quantum entanglement, the system can allow for entanglement, security and simultaneous communication. In order for such communication to occur simultaneously, the nodes must be arranged in an equilateral triangle of an arbitrary size. The system may switch between nodes as nodes move around the sides of the corresponding triangle and the sides of the corresponding triangle are stretched. Using this method, a continuous arrangement of spacecraft and locations (eg, asteroids, satellites) may allow for near-simultaneous communication through the ability to switch between nodes. If concurrency is not required, the same connection can be used for all nodes for security.

In another embodiment, the set of nodes consists of three satellites arranged in a triangle. Each satellite sends a message to the other via laser beams entangled through quantum entanglement. As an example of possible entanglement communication in the present embodiment, the first satellite polarizes the sequence 100011 to the third satellite. The third satellite receives the sequence corresponding to the inversion 011100 of the sequence transmitted by the first satellite. The third satellite re-polarizes the sequence and transmits this sequence 100011 to the second satellite. The second satellite receives the re-polarized sequence 011100, polarizes this sequence and transmits the sequence 100011 to the first satellite. Since the laser beams are entangled with each other, the triangle can be of any size.

Latency can be a serious problem. The ability to create real-time communications over virtually any distance using triangles or higher-dimensional geometries built on the same concept. To produce such real-time communication at almost any distance, the beams must be properly positioned and the triangles must be as close to equilateral as possible. This technique allows any moving laser-connected group of systems to operate as one system as if they were on a single worktable. This feature is important for systems located in external spaces.

As another example of entangled communication possible in this embodiment, a first satellite receives an entangled beam from a second satellite. The second satellite polarizes the sequence, eg the binary signal 010, for transmission as information. The second satellite changes the polarization and continues to polarize the sequence until a connection is determined. This process is performed for all access points of 6 out of 3 satellites. Thereafter, the polarized sequence is immediately received from the second satellite at the third satellite as de-polarized sequence 101 . The third satellite then polarizes the entangled beam received from the first satellite to 010. This latter entangled beam is then received as 101 at the second satellite. This embodiment allows all three nodes to have the same information simply by knowing the source of the transmission and inverting that transmission as needed. The nodes may also respond in reverse order. This example is possible regardless of the distance between nodes.

In another embodiment, the set of nodes may be the set of drones and/or airships in case the set of drones and/or airships is a multiple of 3.

In one embodiment, the review and verification of at least one blockchain ledger for the eligibility of the proposed transaction between the receiver and the transmitter may be made before the transfer of power/data can begin. The transfer will only be made if the transaction is deemed valid and possible.

In one embodiment, the transmitter of power and/or data may be the original power source (ie, where the power is generated) and may be the transmitter where the power/data is stored (as opposed to being generated).

When the transmitter is a power storage device, the power storage device can also sometimes function as a receiver of power/data from a power source. The power source may be a space-based satellite, spacecraft, or other device capable of generating power from the sun and converting that power into a usable energy or data source within the electromagnetic spectrum. For example, the satellite may be similar to the solar satellite 304 of FIG. 3 . The transmitted power (or data) may be microwave energy. In other embodiments, the transmitted power may include energy wavelengths other than microwaves.

When the power source is in space, the power source can transmit power/data to several power storage devices in a distributed network. The distributed network may be located in space, on a celestial body or on Earth, in the air, on land, or in water.

The power storage transmitter may be a satellite or spacecraft in space, a storage device on a celestial body, or a storage device on the ground.

The power storage device may include an array of power storage devices. The array may include, for example, drones deployed worldwide or over a large area.

The power storage device may be mobile (eg, automobile, boat, airplane, etc.). The power storage devices may be stationary and stationary (eg, an energy bank in a power plant, building or smart city, etc.). The power storage device may be a hybrid or tethered system in which the “stationary” power source is not held in a fixed position, but rather is mobile, or the mobile power source is maintained in a fixed position.

In an embodiment, the receiver is also a transmitter. The power and/or data may be transmitted via a receiver/transmitter array. The receiver/transmitter may be in a variety of two-dimensional or three-dimensional topologies. Each receiver/transmitter may be a node in the network. The receiver/transmitter receives power/data from at least one power source or at least one other node and/or transmits power/data to at least one other node. Such an embodiment may allow for an entire array of nodes (eg, drones) that may be distributed over a large area to be powered from a single power source. Such an embodiment may also allow a single power source to power multiple systems from a single location. Additionally, such an embodiment may allow multiple power sources to power a single location.

In one embodiment, network security is established based on the laws of quantum physics.

In one embodiment, the network uses quantum key distribution (QKD). For authentication, QKD transmits quantum states and generates a secret key between two parties respectively connected by quantum channel and public classic channel for post-processing procedures. A quantum secure blockchain uses a multi-layered network for multiple nodes to receive and transmit power, data and/or information.

While the above description provides examples of one or more apparatus, methods, or systems, it will be understood that other apparatuses, methods, or systems may be within the scope of the claims interpreted by one of ordinary skill in the art.

Claims (20)

A wireless power transaction system comprising:
The wireless power transaction system,
a decentralized blockchain application that facilitates wireless transactions between buyers and suppliers, the blockchain application comprising at least one blockchain ledger;
one or more servers that facilitate recording and transmission of the wireless transaction, wherein the one or more servers mediate a wireless power transaction through a digital exchange of money based on generation and use of power;
Including, a wireless power transaction system. According to claim 1,
The wireless power transaction system,
wireless power two-part blockchain currency;
further comprising, wherein the two-part money comprises a first currency and a second currency. 3. The method of claim 2,
the one or more servers,
a trust server for storing the two-part money and fiat money; and
first server - a first server receives fiat money from a buyer transaction device in a first transaction recorded on said at least one blockchain ledger and exchanges said fiat money for two-part money from said trust server; the first currency is provided to the purchaser transaction device and the second currency is held by a first server;
Including, a wireless power transaction system. 4. The method of claim 3,
The wireless power transaction system,
at least one wireless power provider device for receiving and storing power;
further comprising: at least one wireless power purchaser device capable of receiving power from the at least one wireless power provider device. 5. The method of claim 4,
and the purchaser exchanges the first currency for power from the at least one wireless power provider in a second transaction recorded on the at least one blockchain ledger. 5. The method of claim 4,
The at least one wireless power provider device and the first server receive first and second currencies provided to the trusted server in exchange for the fiat currency in a third transaction recorded on the at least one blockchain ledger. combining, the fiat currency is provided to the wireless power supply by the first server in a transaction recorded on the at least one blockchain ledger, and the wireless power transaction system comprises at least one wireless device for transmitting power. A wireless power transaction system, further comprising a power transmitter. 7. The method of claim 6,
The wireless power transaction system,
a plurality of semi-autonomous devices configured as a mobile transmitting or receiving power plant;
further comprising, through the plurality of semi-autonomous devices, an aircraft system capable of navigating, maneuvering, beam riding and charging from one point to another;
wherein the plurality of semi-autonomous devices consists of at least three, the semi-autonomous devices are configured to transmit and receive a quantum entanglement laser beam to exchange information, the plurality of semi-autonomous devices are configured to have an equilateral triangle or arranged in a nearly equilateral triangle, wherein quantum entanglement allows for secure and simultaneous communication between the plurality of semi-autonomous devices;
The semi-autonomous devices include a plurality of tethers for transmitting power and data to, and receiving power and data from, a land-based or water-based system to further distribute power and/or data. A wireless power transaction system configured to serve as power and data hubs coupled to the devices. 7. The method of claim 6,
wherein the at least one power transmitter comprises at least one solar satellite and the at least one wireless power transmitter also transmits data and/or information. 4. The method of claim 3,
The wireless power transaction system,
a plurality of reverse-directional antenna arrays for wireless transmission by base stations for receiving and transmitting power, data and/or information;
Further comprising, a wireless power transaction system. A wireless power transaction method comprising:
The wireless power transaction method comprises:
transmitting electromagnetic radiation from at least one solar satellite to at least one receiving station; and
processing the purchase of power from the supplier transactional device by the purchaser transactional device;
Including, a wireless power transaction method. 11. The method of claim 10,
there is a plurality of aircraft, satellite and ground-based devices configured as a mobile transmitting and/or receiving power plant in which the aircraft system is capable of navigating, maneuvering, beaming and charging from one point to another;
the plurality of aircraft systems, satellite systems and ground-based devices consists of at least three, wherein the aircraft, satellite and ground-based devices are configured to transmit and receive a quantum entangled laser beam to exchange information; Aircraft, satellites and ground-based devices are arranged in an equilateral or near equilateral triangle, whereby quantum entanglement allows for secure and simultaneous communication between satellites so constructed and deployed;
The plurality of aircraft, satellite, and ground-based devices transmit power and data to and receive power and data from and/or receive power and/or data from land-based and/or water-based systems. or to serve as power and data hubs coupled to a plurality of tethers for further distributing data. 11. The method of claim 10,
processing the purchase of electricity comprises processing the purchase of a first one of two-part money by the purchaser transaction device, wherein the two-part currency comprises the first currency and a second currency , a wireless power transaction method. 13. The method of claim 12,
The purchase is
transferring fiat money to a first server by the purchaser transaction device;
transferring the fiat currency by the first server to a trusted server;
receiving, by a first entity, a two-part currency comprising a first currency and a second currency from the oracle server; and
transferring the first currency to the purchaser transaction device by the first server;
Including, a wireless power transaction method. 14. The method of claim 13,
The wireless power transaction method comprises:
recording a first transaction on a public blockchain;
further comprising, wherein the first transaction comprises a transfer of the fiat currency by the purchaser transaction device to the first server and a transfer of the first currency by the first server to the purchaser transaction device; A wireless power transaction method. 13. The method of claim 12,
purchase,
transferring the first currency by the buyer transaction device to a supplier transaction device; and
transmitting power from the at least one wireless power provider device to the at least one wireless power purchaser device;
Including, a wireless power transaction method. 16. The method of claim 15,
Purchasing includes recording a second transaction on a public blockchain, wherein the second transaction includes transfer of the first currency by the purchaser transaction device to the supplier transaction device and to the at least one wireless power provider device. and transmitting power to the at least one wireless power purchaser device by 17. The method of claim 16,
purchase,
combining the first currency and the second currency into a two-part currency by the provider transaction device and the first server;
transferring the two-part currency by the first server to the trust server;
recording a third transaction on a public blockchain, wherein the third transaction comprises a transfer of the two-part money by the first server to the trusted server;
transferring the fiat currency to the first server by the trusted server;
transferring the fiat currency by the first server to the provider device; and
recording a fourth transaction on a private blockchain, wherein the fourth transaction comprises a transfer of the fiat currency by the first server to the provider transaction device;
Including, a wireless power transaction method. A wireless energy transmission system comprising:
The wireless energy transmission system,
A decentralized blockchain application that facilitates wireless energy transfer between a receiver and a transmitter, the blockchain application comprising at least one blockchain ledger;
first server - a first server receives a request for wireless energy from the receiver, the request is recorded on the at least one blockchain ledger, and a first server facilitates wireless energy transfer from the transmitter to the receiver to make -; and
at least one wireless power provider device for receiving and storing power, the at least one wireless power purchaser device capable of receiving power from the at least one wireless power provider device;
Including, a wireless energy transfer system. 19. The method of claim 18,
The wireless energy transmission system,
a quantum secure blockchain network for wireless transmission by a plurality of nodes for receiving and transmitting power, data and/or information;
Further comprising a, wireless energy transfer system. 20. The method of claim 19,
The wireless energy transmission system,
a plurality of aircraft, satellite, or ground-based devices configured as mobile power transmitting and/or receiving power plants;
further comprising, wherein the aircraft system is capable of navigating, maneuvering, beaming and charging from one point to another;
wherein the plurality of aircraft, satellite and ground-based devices comprises at least three, wherein the aircraft, satellite and ground-based devices are configured to transmit and receive quantum entanglement laser beams to exchange information; Ground-based devices are arranged in an equilateral or near equilateral triangle, whereby quantum entanglement allows for secure and simultaneous communication between satellites so constructed and deployed;
The plurality of aircraft, satellite, or land-based devices transmit power and data to and receive power and data from and/or receive power and data from land-based and/or water-based systems. and/or configured to serve as power and data hubs coupled to a plurality of tethers for further distributing data.

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